Sound production and sonic apparatus in deep-living cusk-eels (Genypterus chilensis and Genypterus maculatus)

Parmentier, Éric; Bahri, Mohamed Ali; Plenevaux, Alain; Fine, Michael L.; Estrada, Juan Manuel

doi:10.1016/j.dsr.2018.09.009

Cited by 14 publications

(14 citation statements)

References 57 publications

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“…80 This is especially true in the deep sea, where fish sounds have rarely been studied despite the fact that many species possess sonic muscles presumably used in vocalization. 81,82 Although many fishes and invertebrates do not produce purposeful sounds, it is important to understand that incidental sound production may occur upon physiological and behavioral activity (e.g., specific swimming and feeding mode sounds). Those acoustic marks can be used to assess the presence of individuals for a certain species and are therefore being incorporated into PAM monitoring procedures.…”

Section: Roadmap For the Monitoring Of Ecosystem Indicatorsmentioning

confidence: 99%

New High-Tech Flexible Networks for the Monitoring of Deep-Sea Ecosystems

Aguzzi

Chatzievangelou

Marini

et al. 2019

Environ. Sci. Technol.

108

146

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Section: Roadmap For the Monitoring Of Ecosystem Indicatorsmentioning

confidence: 99%

New High-Tech Flexible Networks for the Monitoring of Deep-Sea Ecosystems

Aguzzi

Chatzievangelou

Marini

et al. 2019

Environ. Sci. Technol.

108

146

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“…Gadiformes, Ophidiiformes and Scorpaeniformes (Ali et al, 2016;Bougis & Ruivo, 1954;Fine et al, 2007Fine et al, , 2018Marshall, 1954;Marshall, 1965;Marshall, 1967;Nguyen et al, 2008;Parmentier, Bahri, et al, 2018;Riera, Rountree, Agagnier, & Juanes, 2020, Table 1). These data support the hypothesis that sound production has evolved independently and sporadically in various lineages, which is in complete accordance with data for shallow water species (Fine & Parmentier, 2015).…”

Section: Fis H Sounds; Natur Al Tag S In the Deep S E A?mentioning

confidence: 99%

“…To date, sound production mechanisms and/or sound emission has been reported in deep‐sea resident fish species of five different families (Macrouridae, Ophidiidae, Bythitidae, Dinematichthyidae and Anoplopomatidae) that belong to three different orders; Gadiformes, Ophidiiformes and Scorpaeniformes (Ali et al., 2016; Bougis & Ruivo, 1954; Fine et al., 2007, 2018; Marshall, 1954; Marshall, 1965; Marshall, 1967; Nguyen et al., 2008; Parmentier, Bahri, et al, 2018; Riera, Rountree, Agagnier, & Juanes, 2020, Table 1). These data support the hypothesis that sound production has evolved independently and sporadically in various lineages, which is in complete accordance with data for shallow water species (Fine & Parmentier, 2015).…”

Section: Fish Sounds; Natural Tags In the Deep Sea?mentioning

confidence: 99%

“…In the case of one of the aforementioned families (i.e., Ophidiidae), different studies on species living in shallower waters clearly support that acoustic communication is an important aspect of these species biology, which likely mediates reproductive interactions. Sound production has been reported in the striped cusk‐eel ( Ophidion marginatum , Ophidiidae; Mann, Bowers‐Altman, & Rountree, 1997; Rountree & Bowers‐Altman, 2002 ) and in Roche's snake blenny ( Ophidion rochei Ophidiidae; Kéver, Lejeune, Michel, & Parmentier, 2016; Parmentier, Bouillac, Dragičević, Dulčić, & Fine, 2010) as well as in two species, the red cusk‐eel ( Genypterus chilensis , Ophidiidae) and the black cusk‐eel ( Genypterus maculatus , Ophidiidae), which can inhabit depths between 50 and 800 m (Parmentier, Bahri, et al, 2018). Interestingly, species from coastal and deep waters possess the same kind of sound producing mechanism.…”

Section: Fish Sounds; Natural Tags In the Deep Sea?mentioning

confidence: 99%

“…Deep‐sea fish acoustic communication is still poorly documented (Rountree, Juanes, Goudey, & Ekstrom, 2012; Wall, Rountree, Pomerleau, & Juanes, 2014). However, many deep‐sea species are likely to be able to emit sounds, because they possess the required anatomical structures (Ali, Mok, & Fine, 2016; Bougis & Ruivo, 1954; Fine et al., 2007; Fine, Ali, Nguyen, Mok, & Parmentier, 2018; Marshall, 1965; Marshall, 1967; Nguyen, Lin, Parmentier, & Fine, 2008; Parmentier, Bahri, Plenevaux, Fine, & Estrada, 2018; Table 1). Why would so many species possess sonic mechanisms if not to use them?…”

Section: Fish Sounds; Natural Tags In the Deep Sea?mentioning

confidence: 99%

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The unexploited potential of listening to deep‐sea fish

Bolgan

Parmentier

2020

Fish and Fisheries

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Ghoti aims to serve as a forum for stimulating and pertinent ideas. Ghoti publishes succinct commentary and opinion that addresses important areas in fish and fisheries science. Ghoti contributions will be innovative and have a perspective that may lead to fresh and productive insight of concepts, issues and research agendas. All Ghoti contributions will be selected by the editors and peer reviewed. Etymology of Ghoti George Bernard Shaw (1856-1950), polymath, playwright, Nobel prize winner, and the most prolific letter writer in history, was an advocate of English spelling reform. He was reportedly fond of pointing out its absurdities by proving that 'fish' could be spelt 'ghoti'. That is: 'gh' as in 'rough', 'o' as in 'women' and 'ti' as in palatial.

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Novel neurocranial fenestrae and expansions in Monomitopus and Selachophidium (Teleostei: Ophidiidae), with comments on the morphology, taxonomy, and evolution of the genera

Girard,

Johnson

2024

Journal of Morphology

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The Ophidiidae is a group of more than 300 species of fishes characterized by elongated, snake‐like bodies and continuous dorsal, anal, and caudal fins. While describing a new species in the genus Monomitopus, we discovered a bilaterally paired fenestra on the dorsomedial surface of the neurocranium. We surveyed the distribution of this fenestra across species of Monomitopus and previously hypothesized allies in the genera Dannevigia, Dicrolene, Homostolus, Neobythites, and Selachophidium, finding variation in its presence and size. We also found a prominent bilaterally paired lateral fenestra and a posterior expansion of the exoccipital in the neurocrania of M. americanus and S. guentheri, with soft tissue connecting the back of the neurocranium to the first epineural and pectoral girdle in S. guentheri. In this study, we describe the distribution of and variation in these features. We integrate morphological characters and DNA data to generate a phylogeny of Monomitopus and allies to understand their relationships and trace the evolutionary history of these novel features. Our results call the monophyly of Monomitopus into question. The presence of the lateral neurocranial fenestra and posterior expansion of the exoccipital support the reclassification of M. americanus as a species of Selachophidium.

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Sound production and sonic apparatus in deep-living cusk-eels (Genypterus chilensis and Genypterus maculatus)

Cited by 14 publications

References 57 publications

New High-Tech Flexible Networks for the Monitoring of Deep-Sea Ecosystems

New High-Tech Flexible Networks for the Monitoring of Deep-Sea Ecosystems

The unexploited potential of listening to deep‐sea fish

Novel neurocranial fenestrae and expansions in Monomitopus and Selachophidium (Teleostei: Ophidiidae), with comments on the morphology, taxonomy, and evolution of the genera

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